Fast Determination of Mitochondria Electrophoretic Mobility Using

Oct 20, 2009 - Fast, continuous separation of mitochondria from rat myoblasts using micro free-flow electrophoresis (µFFE) with online laser-induced ...
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Anal. Chem. 2009, 81, 9267–9273

Fast Determination of Mitochondria Electrophoretic Mobility Using Micro Free-Flow Electrophoresis Vratislav Kostal, Bryan R. Fonslow, Edgar A. Arriaga, and Michael T. Bowser* Department of Chemistry, University of Minnesota, 207 Pleasant Street SE, Minneapolis, Minnesota 55455 Fast, continuous separation of mitochondria from rat myoblasts using micro free-flow electrophoresis (µFFE) with online laser-induced fluorescence detection (LIF) is reported. Mitochondrial electrophoretic profiles were acquired in less than 30 s. In comparison to macroscale FFE instruments, µFFE devices consumed approximately 100-fold less sample, used 10-fold less buffer, and required a 15-fold lower electric field. Mitochondrial electrophoretic mobility distributions measured using µFFE were compared to those measured with a capillary electrophoresis instrument with laser-induced fluorescence detection (CE-LIF). There was high similarity between the two distributions with CE-LIF distribution being offset by 1.8 × 10-4 cm2 V-1 s-1 with respect to the µFFE distribution. We hypothesize that this offset results from the differences in electric field strength used in the techniques. In comparison to CE-LIF, analysis of mitochondria using µFFE greatly decreased separation time and required less separation voltage, while maintaining low sample (125 nL) and buffer (250 µL) volumes. These features together with the potential for collecting separated organelle fractions for further characterization make µFFE a very attractive tool for the high-throughput analysis of organelle subpopulations as well as investigating the fundamentals of the electrophoretic mobility of biological particles. Mitochondria are important organelles that are involved in a range of cellular processes, such as oxidative phosphorylation,1 cell signaling,2 electron transport,3 and apoptosis.4 Variations in mitochondrial structure, morphology, and function may define mitochondrial subpopulations that, if separated, may help understand the role of mitochondria in degenerative disorders,5 cancer,6 and senescence.7 * To whom correspondence should be addressed. Phone: 612-624-8024. Fax: 612-626-7541. E-mail: [email protected]. (1) Balaban, R. S.; Nemoto, S.; Finkel, T. Cell 2005, 120, 483–495. (2) Brookes, P. S.; Yoon, Y. S.; Robotham, J. L.; Anders, M. W.; Sheu, S. S. Am. J. Physiol.: Cell Physiol. 2004, 287, C817–C833. (3) Cadenas, E.; Davies, K. J. A. Free Radical Biol. Med. 2000, 29, 222–230. (4) Green, D. R.; Reed, J. C. Science 1998, 281, 1309–1312. (5) Chan, D. C. Cell 2006, 125, 1241–1252. (6) Brandon, M.; Baldi, P.; Wallace, D. C. Oncogene 2006, 25, 4647–4662. (7) Terman, A.; Dalen, H.; Eaton, J. W.; Neuzil, J.; Brunk, U. T. Exp. Gerontol. 2003, 38, 863–876. 10.1021/ac901508x CCC: $40.75  2009 American Chemical Society Published on Web 10/20/2009

Fluorescence and electron microscopy can be used to measure mitochondrial properties, such as membrane potential, in vivo.8 These techniques have also been useful for identifying mitochondrial subpopulations (e.g., giant mitochondria).9 Further characterization of mitochondrial subpopulations (e.g., characterization of their proteome) requires isolation of mitochondrial subpopulations. Since the mitochondrial surface has a net negative charge at biological pH, electrophoresis could be used as the basis of their separation.10,11 Differences in the composition of the mitochondrial outer membrane gives rise to different surface charge densities and therefore different electrophoretic mobilities.12,13 On the basis of this principle, free-flow electrophoresis (FFE) has become a well-established method for mitochondrial purification.14-16 In FFE, a sample stream is continuously introduced into a separation chamber filled with buffer flowing under laminar flow conditions. Voltage is applied perpendicularly to the flow in the chamber, and charged species are diverted into discrete streams according to their mobilities in the electric field. The main benefit of FFE separation is the capability to continuously collect distinct fractions for subsequent analyses. However, commercial FFE instruments consume large amounts of sample (e.g., approximately milliliters), which is a limiting factor when only small amounts of sample are available (e.g., rare cells or small tissue biopsies). Integration of FFE onto microfluidic devices has gained much attention recently due to potential performance improvements over preparative FFE.17,18 FFE in a microfluidic format (µFFE) offers several advantages over conventional FFE including lower buffer and sample consumption, increased separation speed, better heat dissipation, capability of monitoring separations online, and detection limits in the nanomolar range.19,20 An elegant proof of (8) Duchen, M. R. Mol. Aspects Med. 2004, 25, 365–451. (9) Navratil, M.; Terman, A.; Arriaga, E. A. Exp. Cell Res. 2008, 314, 164– 172. (10) Valdivia, E.; Pease, B.; Gabel, V.; Chan, V. Anal. Biochem. 1973, 51, 146. (11) Rodriguez, M. A.; Armstrong, D. W. J. Chromatogr., B 2004, 800, 7–25. (12) Kostal, V.; Arriaga, E. A. Electrophoresis 2008, 29, 2578–2586. (13) Radko, S. P.; Chrambach, A. Electrophoresis 2002, 23, 1957–1972. (14) Krivankova, L.; Bocek, P. Electrophoresis 1998, 19, 1064–1074. (15) Zischka, H.; Braun, R. J.; Marantidis, E. P.; Buringer, D.; Bornhovd, C.; Hauck, S. M.; Demmer, O.; Gloeckner, C. J.; Reichert, A. S.; Madeo, F.; Ueffing, M. Mol. Cell. Proteomics 2006, 5, 2185–2200. (16) Eubel, H.; Lee, C. P.; Kuo, J.; Meyer, E. H.; Taylor, N. L.; Millar, A. H. Plant J. 2007, 52, 583–594. (17) Zhang, C. X.; Manz, A. Anal. Chem. 2003, 75, 5759–5766. (18) Kohlheyer, D.; Eijkel, J. C. T.; van den Berg, A.; Schasfoort, R. B. M. Electrophoresis 2008, 29, 977–993. (19) Turgeon, R. T.; Bowser, M. T. Anal. Bioanal. Chem. 2009, 394, 187–198.

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principle of the use of a µFFE device in the analysis of organelles used free-flow isoelectric focusing.21 In this report, we demonstrate a fast, continuous electrophoretic separation of mitochondria using a µFFE device with online laser-induced fluorescence detection (µFFE-LIF). Microliter sample volumes containing fluorescently labeled mitochondria isolated from L6 rat myoblasts are continuously streamed into the µFFE device. Electrophoretic mobility profiles are obtained using real-time observation of the separation process. These profiles are similar to those obtained with CE-LIF. EXPERIMENTAL SECTION Chemicals and Reagents. Fluorescein and 10-N-nonyl-acridine orange (NAO) were purchased from Invitrogen (Eugene, OR). Sucrose was purchased from Roche (Indianapolis, IN). Digitonin was obtained from Calbiochem (San Diego, CA). Dimethyl sulfoxide (DMSO) and ethanol were purchased from Fisher Scientific (Pittsburgh, PA). D-Mannitol was purchased from Riedel de-Hae¨n (Seelze, Germany). Poly(vinyl alcohol) (PVA, 99% hydrolyzed; Mw 31-50 kDa), trypsin solution (10×, 5 g/L trypsin, 2 g/L EDTA · 4Na, 8.5 g/L NaCl), N-(2-hydroxyethyl)(piperazine)-N-(ethanesulfonic acid) (HEPES), phosphatebuffered saline (10× PBS, containing 100 mM KH2PO4/ Na2HPO4 solution, pH 7.4, 27 mM KCl, 1370 mM NaCl), potassium hydroxide (KOH), hydrochloric acid (HCl), and tryphan blue were purchased from Sigma (St. Louis, MO). Geneticin, Dulbecco’s modified Eagle’s medium (DMEM), and calf serum were purchased from Gibco. Stock solutions of 1 mM fluorescein and NAO were made in ethanol and DMSO, respectively. The stock solution of 100 g/L digitonin was prepared in DMSO and diluted to 10 mg/mL in buffer M before using. Buffers. Mitochondria isolation buffer (buffer M) contained 70 mM sucrose, 5 mM HEPES, 5 mM EDTA, and 210 mM mannitol. Free-flow electrophoresis buffer (FFE buffer) contained 250 mM sucrose and 10 mM HEPES (pH ) 7.40). Capillary electrophoresis buffer (CE buffer) was prepared by dissolving 0.2% (v/v) PVA in FFE buffer. All buffers were prepared in Milli-Q water, filtered with a 0.22 µm membrane filter, and their pH adjusted to 7.4 by 1 M KOH. Cell Culture. Adherent L6 rat myoblasts were cultured in DMEM medium with 10% bovine serum at 37 °C and 5% CO2 in 75 cm2 vented flasks and split after reaching 90% confluence every 3-4 days. For splitting, L6 cells were rinsed with PBS, lifted with 5 mL of 0.25 g/L trypsin for 5 min, and diluted in fresh medium in 1:20-1:40 ratio. Mitochondria Preparation. All operations during mitochondria sample preparations were performed on ice. Cells were harvested using 5 mL of 0.25 g/L trypsin and washed three times with cold buffer M, counted using a Fuchs-Rosenthal hemocytometer (Hausser Scientific, Horsham, PA), and diluted to 5.1 × 106 cells/mL with buffer M. A 1 mL aliquot of cell suspension was mixed with 10 µL of 10 mg/L digitonin and kept incubated for 5 min on ice. After permeabilization, cells were gently disrupted by six strokes in a Dounce homogenizer with (20) Turgeon, R. T.; Bowser, M. T. Electrophoresis 2009, 30, 1342–1348. (21) Lu, H.; Gaudet, S.; Schmidt, M. A.; Jensen, K. F. Anal. Chem. 2004, 76, 5705–5712.

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0.0005-0.0025 in. of clearance (Kontes, Vinland, NJ). Approximately 90% of cells were disrupted as observed by counting cells in an aliquot of the homogenate treated with tryphan blue. Crude mitochondrial fractions were prepared by differential centrifugation. Briefly, cell lysate was centrifuged at 600g for 10 min to eliminate intact cells, cell debris, and the nuclear fraction. Mitochondria in the supernatant were then labeled with 5 µM NAO for 10 min on ice in the dark. After labeling, mitochondria were pelleted by the centrifugation at 12 000g for 10 min, washed two times by buffer M, and finally resuspended in CE buffer. Chip Fabrication. A two-step etching procedure was used to fabricate a multiple depth µFFE device as described previously.22 Briefly, standard photolithography techniques were used to etch 52 µm deep electrode channels into a 1.1 mm borofloat wafer (Precision Glass & Optics, Santa Ana, CA). A second photolithography step was used to etch the remaining channels. The final depths of the electrode and remaining channels were 71 and 19 µm, respectively. Titanium (100 nm) and platinum (150 nm) layers were deposited followed by a third photolithography procedure to define the electrodes in the side channels. A second wafer, predrilled with access holes and deposited with a ∼90 nm thick layer of amorphous silicon (a-Si), was aligned with the etched, electrode-deposited wafer, and 900 V was applied for 2 h at 450 °C and 5 µbar to anodically bond the two wafers. Nanoports (Upchurch Scientific, Oak Harbor, WA) were attached to the access holes using manufacturer’s procedures. Electrodes were connected to wires using silver conductive epoxy (MG Chemicals, Surrey, BC, Canada). The chip was perfused with 1 M NaOH (Mallinckrodt, Paris, KY) until the channels were clear (180 min) to remove unwanted a-Si. Online LIF Detection. For LIF detection, a 488 nm line from a 150 mW Ar+ laser beam (Melles Griot, Carlsbad, CA) was expanded to a ∼2.5 cm wide by ∼280 µm thick line across the separation channel of the chip. An SMZ 1500 stereomicroscope (Nikon Corp., Tokyo, Japan) mounted with a Cascade 512B CCD camera (Photometrics, Tucson, AZ) was used to collect the fluorescence emission. The microscope was equipped with an Endow GFP band-pass emission filter cube (Nikon Corp.) containing two band-pass filters (450-490 and 500-550 nm) and a dichroic mirror (495 nm cutoff). A 1.6× objective was used for collection with a 0.7× CCD camera lens. Magnifications were adjusted between 2× and 6× using the optical zoom of the microscope. The exposure time for the CCD camera was set 100 ms. MetaVue software (Downington, PA) was used for image collection and processing. µFFE Separation. A schematic illustration of the µFFE device is shown in Figure 1. FFE buffer was pumped at 500 µL/min into the buffer inlet using a 22 syringe pump (Harvard Apparatus). Fluorescein and enriched mitochondria fractions were pumped at 250 nL/min into the 20 µm wide sample inlet using a Pico Plus syringe pump (Harvard Apparatus). On the basis of the channel geometry and the applied flow rate of the separation buffer, mitochondria traveled through the microchip at velocity of 1.63 mm/s. At this flow rate, they passed through the 280 µm thick detection zone placed 2 cm downstream from the injection point (22) Fonslow, B. R.; Barocas, V. H.; Bowser, M. T. Anal. Chem. 2006, 78, 5369– 5374.

Figure 1. Schematic of the µFFE device. Mitochondria are introduced into the device in the absence (A) and presence (B) of an electric field.

after 12 s, thus defining the separation time. Mitochondria were excited for 180 ms, while moving through this zone. Voltages between 0 and 100 V were applied across the channel to separate the mitochondria (light gray area in Figure 1). µFFE Data Analysis. Images of µFFE mitochondrial separations were converted to electrophoretic profiles via the line scan feature in MetaVue software. Over the course of a given separation, 60 consecutive images were acquired. An equal number of background images were then acquired in the absence of mitochondria and averaged to produce a background image. The 60 images of the mitochondrial separation were backgroundsubtracted and averaged to generate a final image. Line scans were generated by integration of the lateral intensity profiles (pixel intensity vs chip width) across the width of the excitation laser line. The rectangular line scan essentially integrated mitochondrion signals over time. Line scans (fluorescence vs horizontal position) were converted to apparent electrophoretic mobility profiles (fluorescence vs electrophoretic mobility) by calculating the electrophoretic mobility associated with each position in the channel considering the electric field and the residence time in the separation channel. In order to compare electrophoretic profiles measured under different separation conditions, electrophoretic mobility data were corrected using the mobility of fluorescein measured under the same conditions. The following equation governing electrophoretic migration in µFFE was used to calculate the electrophoretic mobility shift of mitochondria with respect to fluorescein:

µm,FFE )

dm - df Et

(1)

where µm, FFE is electrophoretic mobility, dm is the migration distance of a mitochondrion at a given voltage, df is the

migration distance of the reference fluorescein stream at the same voltage, E is the applied electric field across the channel (calculated from the applied voltage V and the channel width w, E ) V/w), and t is the residence time of a mitochondrion in the channel from the inlet to detector. Residence time (t) is calculated from the separation buffer linear velocity and the distance to the detector. Histograms of the µFFE mobility profiles were generated by binning mobility data into intervals of equal size (2.5 × 10-5 cm2 V-1 s-1) and normalized. CE-LIF Setup and Data Analysis. Capillary electrophoresis experiments were performed using a laboratory-built CE instrument with postcolumn LIF detection, which has been described previously.23 A 488 nm line from an argon-ion laser (Melles Griot, Irvine, CA) was used as an excitation source. Scattering from bubbles and subcellular particles was removed by a 505 nm longpass filter (Semrock, Rochester, NY). Fluorescence from fluorescein and NAO was selected using an interference filter transmitting in the range of 518-552 nm (535DF35, Omega Optical, Brattleboro, VT). Output from the photomultiplier tubes biased to 1000 V (R1477, Hamamatsu Corp., Bridgewater, NJ) was digitized at 200 Hz using a NiDaq I/O board (PCI-MIO-16XE-50, National Instruments, Austin, TX) and stored as a binary file. The detector was aligned using a continuous injection of 5 × 10-10 M fluorescein in CE buffer at -360 V/cm into the capillary. The limit of detection for fluorescein for the CE-LIF instrument was ∼4 zmol. All separations were carried out in 50 cm long, 50 µm i.d., 150 µm o.d. fused-silica capillaries (Polymicro Technologies, Phoenix, AZ). The capillary was preconditioned by rinsing with 0.5 M KOH for 30 min, 0.5 M HCl for 10 min, water for 10 min, and CE buffer for 10 min at 50 kPa. Between separations, the capillary was rinsed (23) Duffy, C. F.; Gafoor, S.; Richards, D. P.; Admadzadeh, H.; O’Kennedy, R.; Arriaga, E. A. Anal. Chem. 2001, 73, 1855–1861.

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with 0.5 M KOH for 5 min, water for 5 min, and CE buffer for 3 min at 50 kPa. All mitochondrial samples were injected into the capillary using a 4 s hydrodynamic injection at 10.1 kPa and separated at 18 kV. The electroosmotic flow was estimated by the current monitoring method to be (4.98 ± 0.08) × 10-4 cm2 V-1 s-1.24 Fluorescein net mobility in CE buffer was calculated from its migration time in CE-LIF to be (-3.0 ± 0.1) × 10-4 cm2 V-1 s-1. Binary data files were analyzed using Igor Pro software (Wavemetrics, Lake Oswego, OR). Electropherograms were filtered using the median filter function, and peaks with intensities higher than threshold (5 times the standard deviation of the background) were selected. The most intense peaks (4% of the total number of peaks) corresponding to the mitochondria aggregates were removed from the selection. The electrophoretic mobility of each mitochondrion corrected for fluorescein electrophoretic mobility was calculated using following equation:

µm,CE )

(

L2 1 1 V tm tf

)

(2)

where µm,CE is the mitochondria electrophoretic mobility, tm and tf are the migration times of mitochondria and fluorescein, respectively, V is applied voltage, and L is the capillary length. Histograms of the CE mobility profiles were generated by binning mobility values into intervals of equal size (2.5 × 10-5 cm2 V-1 s-1) and the normalizing the peak intensities each bin to the total intensity. The net mobility of fluorescein measured by CE-LIF in the buffer system used in µFFE and CE was used for the calculation of the absolute values of electrophoretic mobilities. To compare two distributions of electrophoretic mobility, a quantile-quantile analysis was used.25 Each q-q plot was generated by plotting the electrophoretic mobility value at a specific quantile (10-100%) of one distribution (e.g., µFFE) versus the value of the same quantile of the second distribution (e.g., CE-LIF). If these two distributions match exactly they would fall along a line with a slope equal to 1. RESULTS AND DISCUSSION Separation and Detection of Mitochondria. Mitochondria isolated from L6 rat myoblasts were fluorescently labeled with NAO (absorption and emission maxima of 495 and 525 nm, respectively) and then streamed into the µFFE channel. In the absence of a separation voltage, mitochondria formed a ∼150 µm wide stream located in the middle of the separation channel (Figure 2A). In the presence of an electric field (95.5 V/cm), the stream spread laterally in the direction of the electric field, which is consistent with mitochondria dispersing across the channel according to their electrophoretic mobilities (Figure 2B). After demonstrating the feasibility of using µFFE to electrophoretically separate mitochondria, we investigated the effects of varying the electric field strength. At high electric fields (i.e., 95.5 V/cm) some mitochondria spread outside the detection region even when using 1× magnification. The use of this magnification resulted in low detection sensitivity and spatial resolution. In (24) Huang, X. H.; Gordon, M. J.; Zare, R. N. Anal. Chem. 1988, 60, 1837– 1838. (25) Whiting, C. E.; Arriaga, E. A. J. Chromatogr., A 2007, 1157, 446–453.

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Figure 2. Dispersion of mitochondria in µFFE caused by application of an electric field. The mitochondria stream is narrow in the absence of an electric field (A) and disperses when a 95.5 V/cm field is applied (B). Images were produced as an overlap of 60 subsequently captured images (scan rate 10 Hz). Dashed lines were added to illustrate the detection region illuminated by the Ar+ laser. Bright spots outside the detection zone were caused by the light scattered at irregularities in the microchip formed during the fabrication process. µFFE buffer, 250 mM sucrose, 10 mM HEPES, pH ) 7.4; flow rate, 500 µL/min; sample flow rate, 250 nL/min; LIF detection, 488 nm excitation, fluorescence collection using 2× magnification, 525 ( 25 nm band-pass filter; CCD camera integration, 100 ms.

addition, this field led to the accumulation of small bubbles in the waste lines that affected the stability of the laminar flow. These bubbles were most likely the result of electrolysis products formed at the electrode surfaces in the electrode channels. We determined that electric fields ranging from 0 to 33.4 V/cm were more suitable because the range of migration distances of the mitochondria decreased to approximately 1.5 mm, allowing the use of a higher magnification (6×) on the imaging microscope. Additionally, at these low electric fields, the laminar flow was more stable due to reduced current and therefore electrolysis. As shown in Figure 3, the migration distance of mitochondria increased as the electric field increased from 0 to 28.6 V/cm. In the absence of an electric field the stream width was 130 ± 5 µm (RSD ) 3.6%, n ) 12) with a stable lateral position of 794 ± 4 µm (RSD ) 0.5%) over 6 s. Dispersion of the mitochondria increased with increasing electric field. These results demonstrate that the electric field in µFFE can be easily adjusted to tailor mitochondrial electrophoretic separations. Individual mitochondria passing through the illuminated region (280 µm), defined by the width of the laser beam, were detected as 160-170 µm long streaks (Figure 3). This is consistent with CCD camera acquisition time (100 ms) and the linear flow velocity (1.63 mm/s). Although it might be possible to analyze individual streaks in the images to determine electrophoretic mobility distributions of mitochondria, it is more practical to use measure the average fluorescence intensity at each position across the detection area to quantify the distribution of mitochondria disper-

Figure 4. Profiles of mitochondria µFFE separations at different electric field strengths. Line scans were produced by averaging 60 consecutive, background-corrected images. Intensity of line scans taken at 0 V/cm was divided by a factor of 2 to fit into the graph. Conditions are the same as in Figure 2.

Figure 3. Separation of mitochondria at different electric fields: (A) no potential, (B) 14.3, (C) 19.1, and (D) 28.6 V/cm. Dashed lines were added to illustrate the detection region illuminated by the Ar+ laser. LIF detection: 5× objective; other conditions are the same as in Figure 2.

sion of across the µFFE detection region (Figure 4). Three major populations were observed in these line scans. Peak 1 migrated approximately 400 µm toward the anode at an electric field of 33.4 V/cm. The position of peak 2 remained nearly constant. Zone 3 is characterized by a collection of intense spikelike events centered at approximately 200 µm toward the cathode. These intense events in area 3 can also observed in the CCD images (see Figure 3). As expected, the width and position of each of these regions were dependent on the electric field strength, confirming the electrophoretic nature of the mitochondrial separation. Since the observed mitochondrial mobility is a function of the intrinsic electrophoretic mobility of mitochondria, electroosmotic flow, and adsorption to the walls of the separation channel,26 below we discuss how these factors may contribute to profiles observed here. Mitochondrial Electrophoretic Mobility Distributions. The intrinsic electrophoretic mobility of biological particles is a function of size, surface charge density, ionic strength of the medium, and the applied electric field.13 Previous studies suggested that size is not an important parameter in explaining differences of electrophoretic mobilities of mitochondrial particles.27 Also, ionic strength does not explain differences in mitochondrial mobilities since all are found in the same medium. Surface charge density, (26) Heidrich, H.-G.; Stahn, R.; Hannig, K. J. Cell Biol. 1970, 46, 137–150. (27) Plummer, D. T. J. Biochem. (Tokyo) 1965, 96, 729.

which defines the ζ-potential, is a function of the ionized functional groups in proteins and phospholipids found on the mitochondrial surface that may include both mitochondrial and nonmitochondrial proteins (e.g., cytoskeletal proteins). Exposure of the inner membrane due to opening of the permeability transition pore and subsequent changes,28 fragmentation and disruption of mitochondria during the isolation procedures,29 removal of the outer membrane,30 and changes in membrane potential21 may also affect the surface charge density thereby resulting in changes in electrophoretic mobility. Thus, it is not surprising to observe three defined features in the observed electrophoretic profiles (Figure 4). Since the charge in mitochondria is less than zero they tend to migrate toward the anode (i.e., left in Figure 4). However, peak 3 migrated toward the cathode relative to zero-field position (see Figure 4). This result is not unexpected since the channel was fabricated from borofloat glass, which bears a negative charge on its surface generating a cathodic electroosmotic flow.31,32 Under such electroosmotic flow regime, the apparent electrophoretic mobility of mitochondria may be greater than zero (i.e., displaced toward the cathode, right in Figure 4). In order to evaluate the potential adsorption of mitochondria inside the channel, the channel walls were inspected by moving the laser excitation line along the channel while looking for immobilized particles. No mitochondria were observed on the (28) Zischka, H.; Larochette, N.; Hoffmann, F.; Hamoller, D.; Jagemann, N.; Lichtmannegger, J.; Jennen, L.; Muller-Hocker, J.; Roggel, F.; Gottlicher, M.; Vollmar, A. M.; Kroemer, G. Anal. Chem. 2008, 80, 5051–5058. (29) Kamo, N.; Muratsugu, M.; Kurihara, K.; Kobatake, Y. FEBS Lett. 1976, 72, 247–250. (30) Fuller, K. M.; Arriaga, E. A. J. Chromatogr., B 2004, 806, 151–159. (31) Fonslow, B. R.; Bowser, M. T. Anal. Chem. 2006, 78, 8236–8244. (32) Fonslow, B. R.; Bowser, M. T. Anal. Chem. 2005, 77, 5706–5710.

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Figure 5. Mitochondria electrophoretic mobility profiles measured using µFFE at different electric fields. Electrophoretic mobilities were calculated from the lateral positions in the channel at various electric field strengths (A). Distributions measured at additional electric fields can be found in the Supporting Information. Three distinct regions were identified (regions 1, 2, and 3). The shapes of the mitochondrial electrophoretic mobility distributions were compared using a quantile-quantile plot (B).

channel walls, suggesting that adsorption was negligible. If a particle adsorbed and then desorbed from the channel wall, its predefined path down the separation channel will not change from diffusion, pressure-driven flow, or electrophoresis since it is only temporarily immobilized. In summary, only the intrinsic electrophoretic mobility and the electroosmotic flow contribute to the observed electrophoretic profiles. It has been reported that the strength of the electric field affects the electrophoretic mobility of biological particles due to processes such as the relaxation effect.13 In order to investigate this possibility, the electrophoretic mobility of mitochondria was calculated using eqs 1 and 2. Figure 5A shows the mitochondrial mobility profiles measured using µFFE at different electric field strengths. Mitochondria net mobility ranged from -2.0 × 10-4 to -5.5 × 10-4 cm2 V-1 s-1. Three regions were observed with maxima at approximately -4.57 × 10-4 (area 1), -3.5 × 10-4 (area 2), and -3.0 × 10-4 cm2 V-1 s-1 (area 3). A q-q plot was used to compare the mobility profiles obtained at different electric fields with the profile obtained at 33.4 V/cm. As shown in Figure 5B, all the data points closely match the diagonal reference line in the q-q plot indicating that the profiles of the mitochondrial electrophoretic mobilities are indistinguishable regardless of the electric field used in the µFFE analysis. Furthermore, these results demonstrate the capability of the µFFE device for characterizing mitochondria electrophoretic mobility distributions at electric potentials as low as 15 V/cm. Comparison of Mitochondrial Distributions Measured Using µFFE and CE-LIF. Electrophoretic mobility profiles of mitochondria analyzed by µFFE were compared to the electrophoretic profiles measured by CE-LIF. CE-LIF analysis of individual mitochondrial particles has been previously used to describe the electrophoretic mobility distributions of mitochondria.33 Figure 6A shows a typical CE-LIF electropherogram of a mitochondria separation. Each spike (approximately 30 ms wide) in the electropherogram represents a single mitochondrial particle passing through the detector. A total of 872 peaks were detected in a single separation, and their migration times and intensities were used to calculate an electrophoretic mobility distribution weighted by event intensity (Figure 6C). These results are consistent with electrophoretic mobilities reported previously (33) Duffy, C. F.; Fuller, K. M.; Malvey, M. W.; O’Kennedy, R.; Arriaga, E. A. Anal. Chem. 2002, 74, 171–176.

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using CE-LIF analysis using covalently modified coated capillaries33 and PVA-coated capillaries.34 Figure 6B is an image of a µFFE separation of the same sample used to obtain the electropherogram shown in Figure 6A. Line scans of 60 images were averaged, converted to electrophoretic mobility, and binned to create an electrophoretic mobility distribution comparable to that obtained using CE-LIF (Figure 6C). CE-LIF and µFFE both yielded bimodal electrophoretic mobility distributions in which the µFFE distribution was offset 1.8 × 10-4 cm2 V-1 s-1 larger (i.e., more negative) than the CE-LIF distribution. Despite the offset, further comparison of these distributions using a q-q plot (Figure 6D) supported the fact that the shapes of the mobility distributions were practically the same (i.e., fall on the reference line). Factors that may contribute to the measured offset could be attributed to differences in (1) electroosmotic flow (EOF), (2) buffer composition, (3) adsorption to the walls, and (4) electric fields used in both methods. The effect of EOF has been accounted for by comparing the mobilities measured by µFFE and CE to that of fluorescein (see eqs 1 and 2). The presence of PVA added to the CE separation buffer as a dynamic coating may affect the intrinsic mobilities of mitochondria.35,36 However, previous work demonstrated that was not the case, because mobilities obtained using such additive were comparable to those obtained with covalently modified coated capillaries.34 Interactions of mitochondria with the capillary walls are not expected to contribute to the observed mobility offset (CE mobility more positive than µFFE mobility), because adsorption onto the capillary wall would result in a longer migration time (i.e., more negative mobility). µFFE separations are not affected by adsorption as described above. Differences in the electric field used in both methods is the most likely cause of the observed shift in mitochondria electrophoretic mobility distributions. This hypothesis is consistent with a phenomenon referred to as the relaxation effect, which accounts for an additional drag on a particles movement resulting from distortion of the surrounding ionic atmosphere in the presence of a high electric field.13 Others have observed increased electrophoretic mobilities of liposomes with decreased electric field.37 This is consistent with the mobility offset seen here where (34) (35) (36) (37)

Whiting, C. E.; Arriaga, E. A. Electrophoresis 2006, 27, 4523–4531. Chrambach, A.; Radko, S. P. Electrophoresis 2000, 21, 259–265. Ohshima, H. Electrophoresis 2002, 23, 1995–2000. Pysher, M. D.; Hayes, M. A. Langmuir 2004, 20, 4369–4375.

Figure 6. Comparison of mitochondria mobility distributions measured using µFFE and CE-LIF. Mitochondria were separated by CE-LIF at 360 V/cm (A) and using µFFE at 14.3 V/cm (B). The lateral position in µFFE and the migration time of each event in CE were used to calculate electrophoretic mobilities. Data were corrected for EOF using fluorescein as an internal standard and segmented into 0.25 × 10-4 cm2 V-1 s-1 wide bins and plotted as a histogram (C). In CE, fluorescence intensity was normalized to the total fluorescence intensity of all detected peaks. The mitochondrial mobility distributions measured using µFFE and CE-LIF were compared using a q-q plot (D).

observed electrophoretic mobilities increased at the low electric field used in µFFE. It should be noted that the electric field used in the µFFE separation was approximately 25-fold lower than that used in CE. This combined with the fact that mobilities measured using µFFE were shown to be independent of electric field (Figure 5) suggests that these low field strengths (0-33.4 V/cm) may be necessary to measure mitochondria mobility distributions in the absence of the relaxation effect. CONCLUSIONS This report describes the fast separation of mitochondria in a µFFE device with online LIF detection. The analysis of a separation profile can be achieved in less than 30 s. This time is markedly shorter when compared to existing FFE or CE methods where a single analysis would typically take approximately 25 min. In contrast to commercial FFE instruments, µFFE requires approximately 100-fold less sample volume and 10-fold less buffer volume. µFFE uses lower electric fields that may be particularly important when studying biological particles that are susceptible to perturbations caused by high electric fields. Another benefit over CE and macroscale FFE devices is the capability to observe the separation process in real-time and quickly change separation conditions or even stop the separation. On the other hand, CELIF offers lower detection limits, which is essential in the analysis of individual mitochondrion properties. Mitochondria with very low fluorescence intensity might not be detected in the µFFE

system and could potentially bias the observed electrophoretic mobility distributions toward larger particles or aggregates. Comparison of CE-LIF and µFFE results may also be a powerful approach for investigating the role of the relaxation effect (and other electric-field-dependent phenomena) on the observed electrophoretic mobility of biological particles. Since µFFE can be used to collect separated mitochondria fractions, this technique could enable characterization of other mitochondrial properties that ultimately would lead to an understanding of the origins of mitochondria electrophoretic mobility and characterization of mitochondrial subpopulations that are relevant to disease and aging. Moreover, µFFE devices may be suitable for analysis of mitochondria and other particles using other separation modes, such as isoelectric focusing. ACKNOWLEDGMENT This work was supported by the National Institutes of Health (R01-AG20866 and R01-GM063533). SUPPORTING INFORMATION AVAILABLE Additional information as noted in text. This material is available free of charge via the Internet at http://pubs.acs.org. Received for review July 7, 2009. Accepted September 23, 2009. AC901508X

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